The effect of pH, ubiquinone depletion and myxothiazol on the reduction kinetics of the prosthetic groups of ubiquinol:cytochrome c oxidoreductase

(1) The kinetics of the reduction by duroquinol of the prosthetic groups of QH2:cytochrome c oxidoreductase and of the formation of ubisemiquinone have been studied using a combination of the freeze-quench technique, low-temperature diffuse-reflectance spectroscopy, EPR and stopped flow. (2) The formation of the antimycin-sensitive ubisemiquinone anion parallels the reduction of both high-potential and low-potential cytochrome b-562. (3) The rates of reduction of both the [2Fe-2S] clusters and cytochromes (c + c1) are pH dependent. There is, however, a pH-dependent discrepancy between their rate of reduction, which can be correlated with the difference in pH dependencies of their midpoint potentials. (4) Lowering the pH or the Q content results in a slower reduction of part of the [2Fe-2S] clusters. It is suggested that one cluster is reduced by a quinol/semiquinone couple and the other by a semiquinone/quinone couple. (5) Myxothiazol inhibits the reduction of the [2Fe-2S] clusters, cytochrome c1 and high-potential cytochrome b-562. (6) The results are consistent with a Q-cycle model describing the pathway of electrons through a dimeric QH2:cytochrome c oxidoreductase.     

Reduction of cytochrome b-561 through the antimycin-sensitive site of the ubiquinol-cytochrome c2 oxidoreductase complex of Rhodopseudomonas sphaeroides

Cytochrome b-561 of the ubiquinol-cytochrome c2 oxidoreductase complex of Rhodopseudomonas sphaeroides is reduced after flash illumination in the presence of myxothiazol in an antimycin-sensitive reaction. Flash-induced reduction was observed over the redox range in which cytochrome b-561 and the Q-pool are both oxidized before the flash. The extent of reduction increased with increasing pH, and was maximal at pH greater than 10.0 where the extent approached that observed in the presence of antimycin following a group of flashes. Reduction of cytochrome b-561 in the presence of myxothiazol showed a lag of approximately 1 ms after the flash, followed by reduction with t 1/2 approximately 6 ms; by analogy with the similar kinetics of the quinol oxidase site, we suggest that the rate is determined by collision with the QH2 produced in the pool on flash excitation.     

The pathway of electrons through OH2:cytochrome c oxidoreductase studied by pre-steady -state kinetics

The kinetic behaviour of the prosthetic groups and the semiquinones in in QH2:cytochrome c oxidoreductase has been studied using a combination of the freeze-quench technique, low-temperature diffuse-reflectance spectroscopy, EPR and stopped flow. (2) In the absence of antimycin, cytochrome b-562 is reduced in two phases separated by a lag time. The initial very rapid reduction phase, that coincides with the formation of the antimycin-sensitive Qin, is ascribed to high-potential cytochrome b-562 and the slow phase to low-potential cytochrome b-562. the two cytochromes are present in a 1:1 molar ratio. The lag time between the two reduction phases decreases with increasing pH. Both the [2 Fe-2S] clusters and cytochrome c1 are reduced monophasically under these conditions, but at a rate lower than that of the initial rapid reduction of cytochrome b-562. (3) In the presence of antimycin and absence of oxidant, cytochrome b-562 is still reduced biphasically, but there is no lag between the two phases. No Qin is formed and both the Fe-S clusters and cytochrome c1 are reduced biphasically, one-half being reduced at the same rate as in the absence of antimycin and the other half 10-times slower. (4) In the presence of antimycin and oxidant, the recently described antimycin-insensitive species of semiquinone anion, Qout (De Vries, S., Albracht, S.P.J., Berden, J.A. and Slater, E.C. (1982) J. Biol. Chem. 256, 11996-11998) is formed at the same rate as that of the reduction of all species of cytochrome b. In this case cytochrome b is reduced in a single phase. (5) The reversible change of the line shape of the EPR spectrum of the [2Fe-2S] cluster 1 is caused by ubiquinone bound in the vicinity of this cluster. (6) The experimental results are consistent with the basic principles of the Q cycle. Because of the multiplicity, stoicheiometry and heterogeneous kinetics of the prosthetic groups, a Q cycle model describing the pathway of electrons through a dimeric QH2:cytochrome c oxidoreductase is proposed.     

The reduction state of the Q-pool regulates the electron flux through the branched respiratory network of Paracoccus denitrificans.

In this work we demonstrate how the reduction state of the Q-pool determines the distribution of electron flow over the two quinol-oxidising branches in Paracoccus denitrificans: one to quinol oxidase, the other via the cytochrome bc1 complex to the cytochrome c oxidases. The dependence of the electron-flow rate to oxygen on the fraction of quinol in the Q-pool was determined in membrane fractions and in intact cells of the wild-type strain, a bc1-negative mutant and a quinol oxidase-negative mutant. Membrane fractions of the bc1-negative mutant consumed oxygen at significant rates only at much higher extents of Q reduction than did the wild-type strain or the quinol oxidase-negative mutant. In the membrane fractions, dependence on the Q redox state was exceptionally strong corresponding to elasticity coefficients close to 2 or higher. In intact cells, the dependence was weaker. In uncoupled cells the dependence of the oxygen-consumption rates on the fractions of quinol in the Q-pool in the wild-type strain and in the two mutants came closer to that found for the membrane fractions. We also determined the dependence for membrane fractions of the wild-type in the absence and presence of antimycin A, an inhibitor of the bc1 complex. The dependence in the presence of antimycin A resembled that of the bc1-negative mutant. These results indicate that electron-flow distribution between the two quinol-oxidising branches in P. denitrificans is not only determined by regulated gene expression but also, and to a larger extent, by the reduction state of the Q-pool.     

Dimeric ubiquinol:cytochrome c reductase of Neurospora mitochondria contains one cooperative ubiquinone-reduction centre

Dimeric ubiquinol:cytochrome c reductase of Neurospora mitochondria was isolated as a protein-Triton complex and free of ubiquinol (Q). The enzyme was incorporated into phosphatidylcholine membranes together with Q. The effects of varying the molar ratio of Q to enzyme on the electron transfer from duroquinol (DHQ2) to the cytochromes c, c1 and b were studied. The rate of electron flow from DQH2 to cytochrome c was 15 times increased by Q and was maximal when one molecule of Q was bound to one enzyme dimer. The apparent Km value for DQH2 of the Q-free enzyme was 5 microM and of the Q-supplemented enzyme 25 microM. The pre-steady-state rate of electron transfer from DQH2 to cytochrome c1 was also 15 times increased by Q and was maximal with one Q molecule bound to one enzyme dimer. This effect of Q was inhibited by antimycin. The pre-steady-state rate of electron transfer from DQH2 to cytochrome b was 5 times decreased when Q was bound to the enzyme and this effect of Q was insensitive to myxothiazol. The H+/2e- stoichiometry with DQH2 as substrate of the Q-supplemented enzyme was 3.6. These results are interpreted in accordance with a Q-cycle mechanism operating in a dimeric cytochrome reductase. Each enzyme monomer catalyses a single electron transfer from the QH2-oxidation centre to the Q-reduction centre and the two monomers cooperate in the reduction of Q to QH2 at one Q-reduction centre. This centre contains two different binding sites for Q. DQH2 does not properly react at the QH2-oxidation centre. DQH2, however, binds to the loose Q-binding site of the Q-reduction centre and reduces the Q bound to the tight Q-binding site of the centre. The QH2 thus formed at the Q-reduction centre serves as electron donor for the QH2-oxidation centre.     

Asymmetric and redox-specific binding of quinone and quinol at center N of the dimeric yeast cytochrome bc1 complex. Consequences for semiquinone stabilization

The cytochrome bc1 complex recycles one of the two electrons from quinol (QH2) oxidation at center P by reducing quinone (Q) at center N to semiquinone (SQ), which is bound tightly. We have analyzed the properties of SQ bound at center N of the yeast bc1 complex. The EPR-detectable signal, which reports SQ bound in the vicinity of reduced bH heme, was abolished by the center N inhibitors antimycin, funiculosin, and ilicicolin H, but was unchanged by the center P inhibitors myxothiazol and stigmatellin. After correcting for the EPR-silent SQ bound close to oxidized bH, we calculated a midpoint redox potential (Em) of approximately 90 mV for all bound SQ. Considering the Em values for bH and free Q, this result indicates that center N preferentially stabilizes SQ.bH(3+) complexes. This favors recycling of the electron coming from center P and also implies a >2.5-fold higher affinity for QH2 than for Q at center N, which would potentially inhibit bH oxidation by Q. Using pre-steady-state kinetics, we show that Q does not inhibit the initial rate of bH reduction by QH2 through center N, but does decrease the extent of reduction, indicating that Q binds only when bH is reduced, whereas QH2 binds when bH is oxidized. Kinetic modeling of these results suggests that formation of SQ at one center N in the dimer allows stabilization of SQ in the other monomer by Q reduction after intradimer electron transfer. This model allows maximum SQ.bH(3+) formation without inhibition of Q binding by QH2.     

Glycine-231 residue of the mouse mitochondrial protonmotive cytochrome b: mutation to aspartic acid deranges electron transport

The mouse LA9 HQN-R11 cytochrome b mutant, in which the glycine residue at position 231 is replaced by aspartic acid, has increased resistance to all inhibitors of the Qn redox center. It is shown here that this single amino acid alteration has multiple and unexpectedly diverse effects upon the mitochondrial protonmotive bc1 complex. (1) The specific activities of both succinate- and ubiquinol-cytochrome c oxidoreductases in isolated mitochondria are reduced by approximately 65% in the mutant. The parallel reductions in both oxidoreductase activities are not compatible with simple Q pool kinetics for mitochondrial electron transport. (2) There is also a reduction in the relative concentration of cytochrome b in the mutant when calculated on the basis of mitochondrial protein; this decrease does not account for more than a small portion of the reduced catalytic fluxes. (3) The increased antimycin resistance of the mutant is lost upon solubilization by the detergent dodecyl maltoside of the bc1 complex from mitochondria. (4) In pre-steady-state assays of cytochrome b reduction by quinol, the mutant shows a reduced extent of reduction. It was observed in other experiments that there was less oxidant-induced extrareduction of cytochrome b in the mutant. These results could arise from a lowering of the midpoint potentials of both the cytochrome b-562 and cytochrome b-566 heme groups. Alternatively, these effects may reflect changes at the Qp and Qn quinone/quinol binding sites. (5) An unexplained observation for the mutant is the increased rate of cytochrome c1 reduction in the presence of myxothiazol. (6) These functional alterations in the LA9 HQN-R11 mutant are not accompanied by detectable changes in the spectral properties of the cytochrome b or c1 heme groups.     

Participation of the iron-sulphur cluster and of the covalently bound coenzyme of trimethylamine dehydrogenase in catalysis.

Bacterial trimethylamine dehydrogenase contains a novel type of covalently bound flavin mononucleotide and a tetrameric iron-sulphur centre. The dehydrogenase takes up 1.5mol of dithionite/mol of enzyme and is thereby converted into the flavin quinol-reduced (4Fe-4S) form, with the expected bleaching of the visible absorption band of the flavin and the emergence of signals of typical reduced ferredoxin in the electronparamagnetic-resonance spectrum. On reduction with a slight excess of substrate, however, unusual absorption and electron-paramagnetic-resonance spectra appear quite rapidly. The latter is attributed to extensive interaction between the reduced (4Fe-4S) centre and the flavin semiquinone. The species of enzyme arising during the catalytic cycle were studied by a combination of rapid-freeze e.p.r. and stopped-flow spectophotometry. The initial reduction of the flavin to the quinol form is far too rapid to be rate-limiting in catalysis, as is the reoxidation of the substrate-reduced enzyme by phenazine methosulphate. Formation of the spin-spin-interacting species from the dihydroflavin is considerably slower, however, and it may be the rate-limiting step in the catalytic cycle, since its rate of formation agrees reasonably well with the catalytic-centre activity determined in steady-state kinetic assays. In addition to the interacting form, a second form of the enzyme was noted during reduction by trimethylamine, differing in absorption spectrum, the structure of which remains to be determined.     

A new species of bound ubisemiquinone anion in QH2: cytochrome c oxidoreductase

Using a combination of EPR and low temperature diffuse reflectance spectroscopy, a new species of semiquinone anion has been detected in QH2:cytochrome c oxidoreductase in submitochondrial particles under conditions of oxidant-induced extra reduction of cytochrome b. In contrast to the previously detected semiquinone anion, this new species is insensitive to antimycin but sensitive to treatment with 2,3-dimercaptopropanol and O2. The two species can easily be distinguished on the basis of their respective EPR properties since they differ in g-value, line width, and microwave power saturation behavior. It is concluded that the two species of semiquinone anion are bound to different domains on QH2:cytochrome c oxidoreductase. The existence of two different semiquinone anions in the enzyme strongly supports a mechanism of electron flow as proposed in the Q-cycle.     

Regulatory interactions in the dimeric cytochrome bc(1) complex: the advantages of being a twin

The dimeric cytochrome bc(1) complex catalyzes the oxidation-reduction of quinol and quinone at sites located in opposite sides of the membrane in which it resides. We review the kinetics of electron transfer and inhibitor binding that reveal functional interactions between the quinol oxidation site at center P and quinone reduction site at center N in opposite monomers in conjunction with electron equilibration between the cytochrome b subunits of the dimer. A model for the mechanism of the bc(1) complex has emerged from these studies in which binding of ligands that mimic semiquinone at center N regulates half-of-the-sites reactivity at center P and binding of ligands that mimic catalytically competent binding of ubiquinol at center P regulates half-of-the-sites reactivity at center N. An additional feature of this model is that inhibition of quinol oxidation at the quinone reduction site is avoided by allowing catalysis in only one monomer at a time, which maximizes the number of redox acceptor centers available in cytochrome b for electrons coming from quinol oxidation reactions at center P and minimizes the leakage of electrons that would result in the generation of damaging oxygen radicals.     

Regulatory interactions in the dimeric cytochrome bc1 complex: The advantages of being a twin

The dimeric cytochrome bc₁ complex catalyzes the oxidation-reduction of quinol and quinone at sites located in opposite sides of the membrane in which it resides. We review the kinetics of electron transfer and inhibitor binding that reveal functional interactions between the quinol oxidation site at center P and quinone reduction site at center N in opposite monomers in conjunction with electron equilibration between the cytochrome b subunits of the dimer. A model for the mechanism of the bc₁ complex has emerged from these studies in which binding of ligands that mimic semiquinone at center N regulates half-of-the-sites reactivity at center P and binding of ligands that mimic catalytically competent binding of ubiquinol at center P regulates half-of-the-sites reactivity at center N. An additional feature of this model is that inhibition of quinol oxidation at the quinone reduction site is avoided by allowing catalysis in only one monomer at a time, which maximizes the number of redox acceptor centers available in cytochrome b for electrons coming from quinol oxidation reactions at center P and minimizes the leakage of electrons that would result in the generation of damaging oxygen radicals.     

The kinetics and thermodynamics of the reduction of cytochrome c by substituted p-benzoquinols in solution

1. The mechanisms by which p-benzoquinol and its derivatives reduce cytochrome c in solution have been investigated. 2. The two major reductants are the species QH- (anionic quinol) and Q.- (anionic semiquinone). A minor route of electron transfer from the fully protonated QH2 species can also occur. 3. The relative contributions of these routes to the overall reduction rate are governed by pH, ionic strength and relative reactant concentrations. 4. For a series of substituted p-benzoquinols, the forward rate constant, k1, of the anionic quinol-mediatd reaction is related to the midpoint potential of the QH-/QH. couple involved in the rate-limiting step, as predicted by the theory of Marcus for outer-sphere electron transfer reactions in a bimolecular collision process. 5. A mechanism for the biological quinol oxidation reactions in mitochondria and chloroplasts is proposed based upon the findings with these reactions in solution.     

Rapid redox equilibrium between the mitochondrial Q pool and cytochrome b during triphasic reduction of cytochrome b by succinate

The reliability of monitoring the redox reactions of cytochrome b using the different wavelengths employed by different authors has been reexamined. It was found that 562-575 nm is suitable in succinate: cytochrome c reductase but not in mitochondria, in which case 562-540 nm is a better pair. Direct optical measurements of the redox reaction kinetics of the mitochondrial Q pool using a commercial dual-wavelength spectrophotometer are possible when succinate is used as the electron donor. Using the correct wavelength pair, and with malonate to slow down the electron input, the reduction course of cytochrome b was still triphasic but a plateau or a turn replaced the oxidation phase previously reported by several authors. At the same time, the reduction course of the Q pool was also triphasic, and in perfect match with that of cytochrome b. Destruction of the Rieske iron-sulfur cluster by British anti-Lewisite (BAL) + O2 treatment or prereduction of the high-potential components made the reduction of both Q and b monophasic. The plot of log (Q/QH2) against log (b3+/b2+) gave a straight line with an n value of 1.7 for cytochrome b at pH 7.4. This n value rose to 2.0 at pH 6.5 and dropped to 1.4 at pH 8.5. On the other hand, the mid-point potential of cytochrome b relative to that of the Q pool remained essentially unchanged between pH 6.5 and 8.4. BAL treatment had a small effect on the midpoint potential of cytochrome b relative to that of the Q pool and had no effect on the n value. Addition of quinone homologues and analogues extended the plateau phase in the reduction of cytochrome b, but exogenous quinones did not equilibrate rapidly with cytochrome b. It was concluded that the appearance of the plateau between the two reduction phases of Q and b is caused by the rapid delivery of electrons to the high-potential components of the respiratory chain as envisaged in the Q cycle; the unexpected n value for cytochrome b suggests a concerted reduction by QH2 of two species of cytochromes b-562.     

The multiplicity and stoichiometry of the prosthetic groups in QH2: cytochrome c oxidoreductase as studied by EPR.

1. The EPR signal in the g = 2 region of the reduced QH2: cytochrome c oxidoreductase as present in submitochondrial particles and the isolated enzyme is an overlap of two signals in a 1 : 1 weighted ratio. Both signals are due to [2Fe-2S]+1 centers. 2. From the signal intensity it is computed that the concentration of each Fe-S center is half that of cytochrome c1. 3. The line shape of one of the Fe-S centers, defined as center 1, is reversibly dependent on the redox state of the b-c1 complex. The change of the line shape cannot be correlated with changes of the redox state of any of the cytochromes in QH2: cytochrome c oxidoreductase. 4. Lie the optical spectrum, the EPR spectrum of the cytochromes is composed of the absorption of at least three different b cytochromes and cytochrome c1. 5. The molar ratio of the prosthetic groups was found to be c1 : b-562 : b-566 : b-558 : center 1 : center 2 = 2 : 2 : 1 : 1 : 1 : 1. The consequences of this stoichiometry are discussed in relation to the basic enzymic unit of QH2 : cytochrome c oxidoreductase.     

Dynamic control on the rate of the reduction of the b type cytochromes in submitochondrial particles.

1. In the presence of antimycin and KCN the reduction of cytochrome b in phosphorylating submitochondrial particles followed a biphasic first-order kinetics. The transition from the first, rapid phase to the second, slow phase occurred while the reduction of chtochromes c + c1 and a through or around the antimycin block was still linear with time. Thus, the phase transition was due to a fall-off in the rate of cytochrome b reduction. 2. The biphasic reduction of cytochrome b was observed over a wide temperature range (0--30 degrees C), with succinate of NADH as electron donors and with phosphorylating particles or coupled rat-heart mitochondria. With rat-heart mitochondria the same biphasic reduction was observed in the presence of either carbonyl cyanide p-trifluoromethoxyphenylhydrazone or oligomycin. 3. In both the rapid and the slow phases, the rate of reduction of cytochrome b-561 was equal to that of b-565. Thus both cytochromes b-561 and b-565 were affected by the mechanism which determined the reduction-rate. Furthermore, each of these cytochromes could be reduced individually with rate constants typical of the slow phase. 4. The proportion of rapidly reduced to slowly reduced cytochrome b was independent of the degree of its reducibility and could be controlled by teh experimental conditions. When antimycin was used as the only inhibitor, 96% of the b-type cytochromes were reduced in the rapid phase. If the c and a-type cytochromes were first reduced by ascorbate and tetramethyl-p-phenylenediamine in the presence of KCN and antimycin, all the b-type cytochromes were fully reduced at the slow-rate. 5. With succinate, the rate of the rapid phase depended on the activation level of the succinic-dehydrogenase. The rate constant of the second phase was unaffected by the succinic dehydrogenase activity, if the preparation was more than 20% active. Furthermore, the rate constant of the slow reduction was the same with succinate, NADH, or even with durohydroquinone (which reacted directly with cytochromes b). 6. It is suggested that cytochrome b can exist in two forms: kinetically active or sluggish. The active form is rapidly reduced by the endogenous quinone (QH2) or durohydroquinone. The rate of the reduction of the active form by succinate or NADH is probably determined by the rate of the reduction of Q by the dehydrogenases. The second form of cytochrome b is characterized by its sluggish reduction by QH2 or durohydroquinone. 7. It is proposed that the transformation from the active to the sluggish form is induced by the reduction of a controlling group, named Y, located on the oxygen side of the antimycin inhibition site. When Y is oxidized, cytochrome b is in its active form, and when Y is reduced, cytochrome b is in its sluggish form. The nature of this kinetic control and a comparison with the mechanism controlling the reducibility of cytochrome b are discussed.     

The dimeric structure of the cytochrome bc(1) complex prevents center P inhibition by reverse reactions at center N

Energy transduction in the cytochrome bc(1) complex is achieved by catalyzing opposite oxido-reduction reactions at two different quinone binding sites. We have determined the pre-steady state kinetics of cytochrome b and c(1) reduction at varying quinol/quinone ratios in the isolated yeast bc(1) complex to investigate the mechanisms that minimize inhibition of quinol oxidation at center P by reduction of the b(H) heme through center N. The faster rate of initial cytochrome b reduction as well as its lower sensitivity to quinone concentrations with respect to cytochrome c(1) reduction indicated that the b(H) hemes equilibrated with the quinone pool through center N before significant catalysis at center P occurred. The extent of this initial cytochrome b reduction corresponded to a level of b(H) heme reduction of 33%-55% depending on the quinol/quinone ratio. The extent of initial cytochrome c(1) reduction remained constant as long as the fast electron equilibration through center N reduced no more than 50% of the b(H) hemes. Using kinetic modeling, the resilience of center P catalysis to inhibition caused by partial pre-reduction of the b(H) hemes was explained using kinetics in terms of the dimeric structure of the bc(1) complex which allows electrons to equilibrate between monomers.     

The mechanism of superoxide production by the antimycin-inhibited mitochondrial Q-cycle

Superoxide production from antimycin-inhibited complex III in isolated mitochondria first increased to a maximum then decreased as substrate supply was modulated in three different ways. In each case, superoxide production had a similar bell-shaped relationship to the reduction state of cytochrome b(566), suggesting that superoxide production peaks at intermediate Q-reduction state because it comes from a semiquinone in the outer quinone-binding site in complex III (Q(o)). Imposition of a membrane potential changed the relationships between superoxide production and b(566) reduction and between b(562) and b(566) redox states, suggesting that b(562) reduction also affects semiquinone concentration and superoxide production. To assess whether this behavior was consistent with the Q-cycle mechanism of complex III, we generated a kinetic model of the antimycin-inhibited Q(o) site. Using published rate constants (determined without antimycin), with unknown rate constants allowed to vary, the model failed to fit the data. However, when we allowed the rate constant for quinol oxidation to decrease 1000-fold and the rate constant for semiquinone oxidation by b(566) to depend on the b(562) redox state, the model fit the energized and de-energized data well. In such fits, quinol oxidation was much slower than literature values and slowed further when b(566) was reduced, and reduction of b(562) stabilized the semiquinone when b(566) was oxidized. Thus, superoxide production at Q(o) depends on the reduction states of b(566) and b(562) and fits the Q-cycle only if particular rate constants are altered when b oxidation is prevented by antimycin. These mechanisms limit superoxide production and short circuiting of the Q-cycle when electron transfer slows.     

The oxidation-reduction kinetics of cytochromes b, c1 and c in initially fully reduced mitochondrial membranes are in agreement with the Q-cycle hypothesis

Stopped-flow experiments were performed to distinguish between two hypotheses, the Q-cycle and the SQ-cycle, each describing the pathway of electron transfer in the QH2:cytochrome c oxidoreductases. It was observed that, when mitochondrial membranes from the yeast Saccharomyces cerevisiae were poised at a low redox potential with appropriate amounts of sodium dithionite to completely reduce cytochrome b, the kinetics of oxidation of cytochrome b showed a lag period of maximally 100 ms. Under the same experimental conditions, the oxidation-reduction kinetics of cytochromes c + c1 showed transient behaviour. These results do not support the presence of a mobile species of semiquinone in the QH2:cytochrome c oxidoreductases, as envisaged in the SQ-cycle, but are consistent with a Q-cycle mechanism in which the two quinone-binding domains do not exchange electrons directly on the timescale of turnover of the enzyme.     

The effect of pH,ubiquinone depletion and myxothiazol on the reduction kinetics of the prosthetic groups of ubiquinol: Cytochrome c oxidoreductase

(1) The kinetics of the reduction by duroquinol of the prosthetic groups of QH₂: cytochrome c oxidoreductase and of the formation of ubisemiquinone have been studied using a combination of the freeze-quench technique, low-temperature diffuse-reflectance spectroscopy, EPR and stopped flow. (2) The formation of the antimycin-sensitive ubisemiquinone anion parallels the reduction of both high-potential and low-potential cytochrome b-562. (3) The rates of reduction of both the [2Fe-2S] clusters and cytochromes (c + c₁) are pH dependent. There is, however, a pH-dependent discrepancy between their rate of reduction, which can be correlated with the difference in pH dependencies of their midpoint potentials. (4) Lowering the pH or the Q content results in a slower reduction of part of the [2Fe-2S] clusters. It is suggested that one cluster is reduced by a quinol/semiquinone couple and the other by a semiquinone/quinone couple. (5) Myxothiazol inhibits the reduction of the [2Fe-2S] clusters, cytochrome c₁ and high-potential cytochrome b-562. (6) The results are consistent with a Q-cycle model describing the pathway of electrons through a dimeric QH₂: cytochrome c oxidoreductase.     

Discrete catalytic sites for quinone in the ubiquinol-cytochrome c2 oxidoreductase of Rhodopseudomonas capsulata. Evidence from a mutant defective in ubiquinol oxidation

A non-photosynthetic mutant (Ps-) of Rhodopseudomonas capsulata, designated R126, was analyzed for a defect in the cyclic electron transfer system. Compared to a Ps+ strain MR126, the mutant was shown to have a full complement of electron transfer components (reaction centers, ubiquinone-10, cytochromes b, c1, and c2, the Rieske 2-iron, 2-sulfur (Rieske FeS) center, and the antimycin-sensitive semiquinone). Functionally, mutant R126 failed to catalyze complete cytochrome c1 + c2 re-reduction or cytochrome b reduction following a short (10 microseconds) flash of actinic light. Evidence (from flash-induced carotenoid band shift) was characteristic of inhibition of electron transfer proximal to cytochrome c1 of the ubiquinol-cytochrome c2 oxidoreductase. Three lines of evidence indicate that the lesion of R126 disrupts electron transfer from quinol to Rieske FeS: 1) the degree of cytochrome c1 + c2 re-reduction following a flash is indicative of electron transfer from Rieske FeS to cytochrome c1 + c2 without redox equilibration with an additional electron from a quinol; 2) inhibitors that act at the Qz site and raise the Rieske FeS midpoint redox potential (Em), namely 5-undecyl-6-hydroxy-4,7-dioxobenzothiazole or 3-alkyl-2-hydroxy-1,4-napthoquinone, have no effect on cytochrome c1 + c2 oxidation in R126; 3) the Rieske FeS center, although it exhibits normal redox behavior, is unable to report the redox state of the quinone pool, as metered by its EPR line shape properties. Flash-induced proton binding in R126 is indicative of normal functional primary (QA) and secondary (QB) electron acceptor activity of the photosynthetic reaction center. The Qc functional site of cytochrome bc1 is intact in R126 as measured by the existence of antimycin-sensitive, flash-induced cytochrome b reduction.